Interplay between polarization, strain, and defect pairs in Fe-doped SrMnO3-δ

Defect chemistry, strain, and structural, magnetic, and electronic degrees of freedom constitute a rich space for the design of functional properties in transition-metal oxides. Here, we show that it is possible to engineer polarity and ferroelectricity in nonpolar perovskite oxides via polar defect pairs formed by anion vacancies coupled to substitutional cations. We use a self-consistent site-dependent approach employing with a correction that accounts for local structural and chemical changes upon defect creation and which is crucial to reconcile predictions with the available experimental data. Our results for Fe-doped oxygen-deficient SrMnO3 show that substitutional Fe and oxygen vacancies can promote polarity due to an off-center displacement of the defect charge resulting in a net electric dipole moment, which polarizes the lattice in the defect neighborhood. The formation of these defects and the resulting polarization can be tuned by epitaxial strain, resulting in enhanced polarization also for strain values lower than the ones necessary to induce a polar phase transition in undoped SrMnO3. For high enough defect concentrations, these defect dipoles couple in a parallel fashion, thus enabling defect- and strain-based engineering of ferroelectricity in SrMnO3.

Automated summary

Defect chemistry, strain, and structural, magnetic, and electronic degrees of freedom are important factors for designing functional properties in transition-metal oxides. The study demonstrates the possibility of engineering polarity and ferroelectricity in nonpolar perovskite oxides through polar defect pairs formed by anion vacancies coupled to substitutional cations. It also shows that the formation of these defects and resulting polarization can be tuned by epitaxial strain.